Reconstruction using witness complexes

Leonidas J. Guibas; Steve Y. Oudot

doi:10.1007/s00454-008-9094-6

Reconstruction using witness complexes

Leonidas J. Guibas
, Steve Y. Oudot

Stanford University

Research output: Contribution to journal › Article › peer-review

Abstract

We present a novel reconstruction algorithm that, given an input point set sampled from an object S, builds a one-parameter family of complexes that approximate S at different scales. At a high level, our method is very similar in spirit to Chew's surface meshing algorithm, with one notable difference though: the restricted Delaunay triangulation is replaced by the witness complex, which makes our algorithm applicable in any metric space. To prove its correctness on curves and surfaces, we highlight the relationship between the witness complex and the restricted Delaunay triangulation in 2d and in 3d. Specifically, we prove that both complexes are equal in 2d and closely related in 3d, under some mild sampling assumptions.

Original language	English
Pages (from-to)	325-356
Number of pages	32
Journal	Discrete and Computational Geometry
Volume	40
Issue number	3
DOIs	https://doi.org/10.1007/s00454-008-9094-6
Publication status	Published - 1 Oct 2008
Externally published	Yes

Keywords

Delaunay triangulation
Reconstruction
Sampling
Witness complex

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10.1007/s00454-008-9094-6

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abstract = "We present a novel reconstruction algorithm that, given an input point set sampled from an object S, builds a one-parameter family of complexes that approximate S at different scales. At a high level, our method is very similar in spirit to Chew's surface meshing algorithm, with one notable difference though: the restricted Delaunay triangulation is replaced by the witness complex, which makes our algorithm applicable in any metric space. To prove its correctness on curves and surfaces, we highlight the relationship between the witness complex and the restricted Delaunay triangulation in 2d and in 3d. Specifically, we prove that both complexes are equal in 2d and closely related in 3d, under some mild sampling assumptions.",

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N2 - We present a novel reconstruction algorithm that, given an input point set sampled from an object S, builds a one-parameter family of complexes that approximate S at different scales. At a high level, our method is very similar in spirit to Chew's surface meshing algorithm, with one notable difference though: the restricted Delaunay triangulation is replaced by the witness complex, which makes our algorithm applicable in any metric space. To prove its correctness on curves and surfaces, we highlight the relationship between the witness complex and the restricted Delaunay triangulation in 2d and in 3d. Specifically, we prove that both complexes are equal in 2d and closely related in 3d, under some mild sampling assumptions.

AB - We present a novel reconstruction algorithm that, given an input point set sampled from an object S, builds a one-parameter family of complexes that approximate S at different scales. At a high level, our method is very similar in spirit to Chew's surface meshing algorithm, with one notable difference though: the restricted Delaunay triangulation is replaced by the witness complex, which makes our algorithm applicable in any metric space. To prove its correctness on curves and surfaces, we highlight the relationship between the witness complex and the restricted Delaunay triangulation in 2d and in 3d. Specifically, we prove that both complexes are equal in 2d and closely related in 3d, under some mild sampling assumptions.

KW - Delaunay triangulation

KW - Reconstruction

KW - Sampling

KW - Witness complex

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SP - 325

EP - 356

JO - Discrete and Computational Geometry

JF - Discrete and Computational Geometry

IS - 3

ER -

Reconstruction using witness complexes

Abstract

Keywords

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